/*
 * Copyright 2015 Google Inc.
 *
 * Use of this source code is governed by a BSD-style license that can be
 * found in the LICENSE file.
 */

#include "gr_triangulator.hpp"
#include "gr_inner_fan_triangulator.hpp"
#include "rive/math/math_types.hpp"

#include <cmath>
#include <map>
#include <utility>
#include <sstream>
#include <catch.hpp>

class GrRecordingContext;
class SkShader;
struct GrContextOptions;

#if !defined(SK_ENABLE_OPTIMIZE_SIZE)

/*
 * These tests pass by not crashing, hanging or asserting in Debug.
 */

using namespace rive;
using CreatePathFn = RawPath (*)();
#define SkBits2Float(X) rive::math::bit_cast<float, uint32_t>(X)

CreatePathFn kNonEdgeAAPaths[] = {
    // Tests active edges made inactive by splitting.
    // Also tests active edge list forced into an invalid ordering by
    // splitting (mopped up in cleanup_active_edges()).
    []() -> RawPath {
        RawPath path;
        path.moveTo(229.127044677734375f, 67.34100341796875f);
        path.lineTo(187.8097381591796875f, -6.7729740142822265625f);
        path.lineTo(171.411407470703125f, 50.94266510009765625f);
        path.lineTo(245.5253753662109375f, 9.6253643035888671875f);
        path.moveTo(208.4683990478515625f, 30.284009933471679688f);
        path.lineTo(171.411407470703125f, 50.94266510009765625f);
        path.lineTo(187.8097381591796875f, -6.7729740142822265625f);
        return path;
    },

    // Intersections which fall exactly on the current vertex, and require
    // a restart of the intersection checking.
    []() -> RawPath {
        RawPath path;
        path.moveTo(314.483551025390625f, 486.246002197265625f);
        path.lineTo(385.41949462890625f, 532.8087158203125f);
        path.lineTo(373.232879638671875f, 474.05938720703125f);
        path.lineTo(326.670166015625f, 544.995361328125f);
        path.moveTo(349.951507568359375f, 509.52734375f);
        path.lineTo(373.232879638671875f, 474.05938720703125f);
        path.lineTo(385.41949462890625f, 532.8087158203125f);
        return path;
    },

    // Tests active edges which are removed by splitting.
    []() -> RawPath {
        RawPath path;
        path.moveTo(343.107391357421875f, 613.62176513671875f);
        path.lineTo(426.632415771484375f, 628.5740966796875f);
        path.lineTo(392.3460693359375f, 579.33544921875f);
        path.lineTo(377.39373779296875f, 662.86041259765625f);
        path.moveTo(384.869873046875f, 621.097900390625f);
        path.lineTo(392.3460693359375f, 579.33544921875f);
        path.lineTo(426.632415771484375f, 628.5740966796875f);
        return path;
    },

    // Collinear edges merged in set_top().
    // Also, an intersection between left and right enclosing edges which
    // falls above the current vertex.
    []() -> RawPath {
        RawPath path;
        path.moveTo(545.95751953125f, 791.69854736328125f);
        path.lineTo(612.05816650390625f, 738.494140625f);
        path.lineTo(552.4056396484375f, 732.0460205078125f);
        path.lineTo(605.61004638671875f, 798.14666748046875f);
        path.moveTo(579.00787353515625f, 765.0963134765625f);
        path.lineTo(552.4056396484375f, 732.0460205078125f);
        path.lineTo(612.05816650390625f, 738.494140625f);
        return path;
    },

    // Tests active edges which are made inactive by set_top().
    []() -> RawPath {
        RawPath path;
        path.moveTo(819.2725830078125f, 751.77447509765625f);
        path.lineTo(820.70904541015625f, 666.933837890625f);
        path.lineTo(777.57049560546875f, 708.63592529296875f);
        path.lineTo(862.4111328125f, 710.0723876953125f);
        path.moveTo(819.99078369140625f, 709.3541259765625f);
        path.lineTo(777.57049560546875f, 708.63592529296875f);
        path.lineTo(820.70904541015625f, 666.933837890625f);
        return path;
    },

    []() -> RawPath {
        RawPath path;
        path.moveTo(823.33209228515625f, 749.052734375f);
        path.lineTo(823.494873046875f, 664.20013427734375f);
        path.lineTo(780.9871826171875f, 706.5450439453125f);
        path.lineTo(865.8397216796875f, 706.70782470703125f);
        path.moveTo(823.4134521484375f, 706.6263427734375f);
        path.lineTo(780.9871826171875f, 706.5450439453125f);
        path.lineTo(823.494873046875f, 664.20013427734375f);
        return path;
    },

    []() -> RawPath {
        RawPath path;
        path.moveTo(954.862548828125f, 562.8349609375f);
        path.lineTo(899.32818603515625f, 498.679443359375f);
        path.lineTo(895.017578125f, 558.52435302734375f);
        path.lineTo(959.17315673828125f, 502.990081787109375f);
        path.moveTo(927.0953369140625f, 530.7572021484375f);
        path.lineTo(895.017578125f, 558.52435302734375f);
        path.lineTo(899.32818603515625f, 498.679443359375f);
        return path;
    },

    []() -> RawPath {
        RawPath path;
        path.moveTo(958.5330810546875f, 547.35516357421875f);
        path.lineTo(899.93109130859375f, 485.989013671875f);
        path.lineTo(898.54901123046875f, 545.97308349609375f);
        path.lineTo(959.9151611328125f, 487.37109375f);
        path.moveTo(929.2320556640625f, 516.67205810546875f);
        path.lineTo(898.54901123046875f, 545.97308349609375f);
        path.lineTo(899.93109130859375f, 485.989013671875f);
        return path;
    },

    []() -> RawPath {
        RawPath path;
        path.moveTo(389.8609619140625f, 369.326873779296875f);
        path.lineTo(470.6290283203125f, 395.33697509765625f);
        path.lineTo(443.250030517578125f, 341.9478759765625f);
        path.lineTo(417.239959716796875f, 422.7159423828125f);
        path.moveTo(430.244964599609375f, 382.3319091796875f);
        path.lineTo(443.250030517578125f, 341.9478759765625f);
        path.lineTo(470.6290283203125f, 395.33697509765625f);
        return path;
    },

    []() -> RawPath {
        RawPath path;
        path.moveTo(20, 20);
        path.lineTo(50, 80);
        path.lineTo(20, 80);
        path.moveTo(80, 50);
        path.lineTo(50, 50);
        path.lineTo(20, 50);
        return path;
    },

    []() -> RawPath {
        RawPath path;
        path.moveTo(257.19439697265625f, 320.876617431640625f);
        path.lineTo(190.113037109375f, 320.58978271484375f);
        path.lineTo(203.64404296875f, 293.8145751953125f);
        path.moveTo(203.357177734375f, 360.896026611328125f);
        path.lineTo(216.88824462890625f, 334.120819091796875f);
        path.lineTo(230.41925048828125f, 307.345611572265625f);
        return path;
    },

    // A degenerate segments case, where both upper and lower segments of
    // a split edge must remain active.
    []() -> RawPath {
        RawPath path;
        path.moveTo(231.9331207275390625f, 306.2012939453125f);
        path.lineTo(191.4859161376953125f, 306.04547119140625f);
        path.lineTo(231.0659332275390625f, 300.2642822265625f);
        path.moveTo(189.946807861328125f, 302.072265625f);
        path.lineTo(179.79705810546875f, 294.859771728515625f);
        path.lineTo(191.0016021728515625f, 296.165679931640625f);
        path.moveTo(150.8942108154296875f, 304.900146484375f);
        path.lineTo(179.708892822265625f, 297.849029541015625f);
        path.lineTo(190.4742279052734375f, 299.11895751953125f);
        return path;
    },

    // Handle the case where edge.dist(edge.fTop) != 0.0.
    []() -> RawPath {
        RawPath path;
        path.moveTo(0.0f, 400.0f);
        path.lineTo(138.0f, 202.0f);
        path.lineTo(0.0f, 202.0f);
        path.moveTo(12.62693023681640625f, 250.57464599609375f);
        path.lineTo(8.13896942138671875f, 254.556884765625f);
        path.lineTo(-18.15641021728515625f, 220.40203857421875f);
        path.lineTo(-15.986493110656738281f, 219.6513519287109375f);
        path.moveTo(36.931194305419921875f, 282.485504150390625f);
        path.lineTo(15.617521286010742188f, 261.2901611328125f);
        path.lineTo(10.3829498291015625f, 252.565765380859375f);
        path.lineTo(-16.165292739868164062f, 222.646026611328125f);
        return path;
    },

    // A degenerate segments case which exercises inactive edges being
    // made active by splitting.
    []() -> RawPath {
        RawPath path;
        path.moveTo(690.62127685546875f, 509.25555419921875f);
        path.lineTo(99.336181640625f, 511.71405029296875f);
        path.lineTo(708.362548828125f, 512.4349365234375f);
        path.lineTo(729.9940185546875f, 516.3114013671875f);
        path.lineTo(738.708984375f, 518.76995849609375f);
        path.lineTo(678.3463134765625f, 510.0819091796875f);
        path.lineTo(681.21795654296875f, 504.81378173828125f);
        path.moveTo(758.52764892578125f, 521.55963134765625f);
        path.lineTo(719.1549072265625f, 514.50372314453125f);
        path.lineTo(689.59063720703125f, 512.0628662109375f);
        path.lineTo(679.78216552734375f, 507.447845458984375f);
        return path;
    },

    // Tests vertices which become "orphaned" (ie., no connected edges)
    // after simplification.
    []() -> RawPath {
        RawPath path;
        path.moveTo(217.326019287109375f, 166.4752960205078125f);
        path.lineTo(226.279266357421875f, 170.929473876953125f);
        path.lineTo(234.3973388671875f, 177.0623626708984375f);
        path.lineTo(262.0921630859375f, 188.746124267578125f);
        path.moveTo(196.23638916015625f, 174.0722198486328125f);
        path.lineTo(416.15277099609375f, 180.138214111328125f);
        path.lineTo(192.651947021484375f, 304.0228271484375f);
        return path;
    },

    []() -> RawPath {
        RawPath path;
        path.moveTo(0.0f, 0.0f);
        path.lineTo(10000.0f, 0.0f);
        path.lineTo(0.0f, -1.0f);
        path.lineTo(10000.0f, 0.000001f);
        path.lineTo(0.0f, -30.0f);
        return path;
    },

    // Reduction of Nebraska-StateSeal.svg. Floating point error causes the
    // same edge to be added to more than one poly on the same side.
    []() -> RawPath {
        RawPath path;
        path.moveTo(170.8199920654296875, 491.86700439453125);
        path.lineTo(173.7649993896484375, 489.7340087890625);
        path.lineTo(174.1450958251953125, 498.545989990234375);
        path.lineTo(171.998992919921875, 500.88201904296875);
        path.moveTo(168.2922515869140625, 498.66265869140625);
        path.lineTo(169.8589935302734375, 497.94500732421875);
        path.lineTo(172, 500.88299560546875);
        path.moveTo(169.555267333984375, 490.70111083984375);
        path.lineTo(173.7649993896484375, 489.7340087890625);
        path.lineTo(170.82000732421875, 491.86700439453125);
        return path;
    },

    // A shape with a vertex collinear to the right hand edge.
    // This messes up find_enclosing_edges.
    []() -> RawPath {
        RawPath path;
        path.moveTo(80, 20);
        path.lineTo(80, 60);
        path.lineTo(20, 60);
        path.moveTo(80, 50);
        path.lineTo(80, 80);
        path.lineTo(20, 80);
        return path;
    },

    // Exercises the case where an edge becomes collinear with *two* of its
    // adjacent neighbour edges after splitting.
    // This is a reduction from
    // http://mooooo.ooo/chebyshev-sine-approximation/horner_ulp.svg
    []() -> RawPath {
        RawPath path;
        path.moveTo(351.99298095703125, 348.23046875);
        path.lineTo(351.91876220703125, 347.33984375);
        path.lineTo(351.91876220703125, 346.1953125);
        path.lineTo(351.90313720703125, 347.734375);
        path.lineTo(351.90313720703125, 346.1328125);
        path.lineTo(351.87579345703125, 347.93359375);
        path.lineTo(351.87579345703125, 345.484375);
        path.lineTo(351.86407470703125, 347.7890625);
        path.lineTo(351.86407470703125, 346.2109375);
        path.lineTo(351.84844970703125, 347.63763427734375);
        path.lineTo(351.84454345703125, 344.19232177734375);
        path.lineTo(351.78204345703125, 346.9483642578125);
        path.lineTo(351.758636474609375, 347.18310546875);
        path.lineTo(351.75469970703125, 346.75);
        path.lineTo(351.75469970703125, 345.46875);
        path.lineTo(352.5546875, 345.46875);
        path.lineTo(352.55078125, 347.01953125);
        path.lineTo(351.75079345703125, 347.02313232421875);
        path.lineTo(351.74688720703125, 346.15203857421875);
        path.lineTo(351.74688720703125, 347.646148681640625);
        path.lineTo(352.5390625, 346.94140625);
        path.lineTo(351.73907470703125, 346.94268798828125);
        path.lineTo(351.73516845703125, 344.48565673828125);
        path.lineTo(352.484375, 346.73828125);
        path.lineTo(351.68438720703125, 346.7401123046875);
        path.lineTo(352.4765625, 346.546875);
        path.lineTo(351.67657470703125, 346.54937744140625);
        path.lineTo(352.47265625, 346.75390625);
        path.lineTo(351.67266845703125, 346.756622314453125);
        path.lineTo(351.66876220703125, 345.612091064453125);
        return path;
    },

    // A path which contains out-of-range colinear intersections.
    []() -> RawPath {
        RawPath path;
        path.moveTo(0, 63.39080047607421875);
        path.lineTo(-0.70804601907730102539, 63.14350128173828125);
        path.lineTo(-7.8608899287380243391e-17, 64.14080047607421875);
        path.moveTo(0, 64.14080047607421875);
        path.lineTo(44.285900115966796875, 64.14080047607421875);
        path.lineTo(0, 62.64080047607421875);
        path.moveTo(21.434900283813476562, -0.24732701480388641357);
        path.lineTo(-0.70804601907730102539, 63.14350128173828125);
        path.lineTo(0.70804601907730102539, 63.6381988525390625);
        return path;
    },

#if 0
    // A path which results in infs and nans when conics are converted to quads.
    []() -> RawPath {
         RawPath path;
         path.moveTo(-2.20883e+37f, -1.02892e+37f);
         path.conicTo(-2.00958e+38f, -9.36107e+37f, -1.7887e+38f, -8.33215e+37f, 0.707107f);
         path.conicTo(-1.56782e+38f, -7.30323e+37f, 2.20883e+37f, 1.02892e+37f, 0.707107f);
         path.conicTo(2.00958e+38f, 9.36107e+37f, 1.7887e+38f, 8.33215e+37f, 0.707107f);
         path.conicTo(1.56782e+38f, 7.30323e+37f, -2.20883e+37f, -1.02892e+37f, 0.707107f);
         return path;
    },
#endif

#if 0
    // A quad which generates a huge number of points (>2B) when uniformly
    // linearized. This should not hang or OOM.
    []() -> RawPath {
        RawPath path;
        path.moveTo(10, 0);
        path.lineTo(0, 0);
        path.quadTo(10, 0, 0, 8315084722602508288);
        return path;
    },
#endif

    // A path which hangs during simplification. It produces an edge which is
    // to the left of its own endpoints, which causes an infinite loop in the
    // right-enclosing-edge splitting.
    []() -> RawPath {
        RawPath path;
        path.moveTo(0.75001740455627441406, 23.051967620849609375);
        path.lineTo(5.8471612930297851562, 22.731662750244140625);
        path.lineTo(10.749670028686523438, 22.253145217895507812);
        path.lineTo(13.115868568420410156, 22.180681228637695312);
        path.lineTo(15.418928146362304688, 22.340015411376953125);
        path.lineTo(17.654022216796875, 22.82159423828125);
        path.lineTo(19.81632232666015625, 23.715869903564453125);
        path.lineTo(40, 0);
        path.lineTo(5.5635203441547955577e-15, 0);
        path.lineTo(5.5635203441547955577e-15, 47);
        path.lineTo(-1.4210854715202003717e-14, 21.713298797607421875);
        path.lineTo(0.75001740455627441406, 21.694292068481445312);
        path.lineTo(0.75001740455627441406, 23.051967620849609375);
        return path;
    },

    // Reduction from skbug.com/7911 that causes a crash due to splitting a
    // zombie edge.
    []() -> RawPath {
        RawPath path;
        path.moveTo(0, 1.0927740941146660348e+24);
        path.lineTo(2.9333931225865729333e+32, 16476101);
        path.lineTo(1.0927731573659435417e+24, 1.0927740941146660348e+24);
        path.lineTo(1.0927740941146660348e+24, 3.7616281094287041715e-37);
        path.lineTo(1.0927740941146660348e+24, 1.0927740941146660348e+24);
        path.lineTo(1.3061803026169399536e-33, 1.0927740941146660348e+24);
        path.lineTo(4.7195362919941370727e-16, -8.4247545146051822591e+32);
        return path;
    },

    // From crbug.com/844873. Crashes trying to merge a zombie edge.
    []() -> RawPath {
        RawPath path;
        path.moveTo(316.000579833984375, -4338355948977389568);
        path.lineTo(1.5069369808623501312e+20, 75180972320904708096.0);
        path.lineTo(1.5069369808623501312e+20, 75180972320904708096.0);
        path.lineTo(771.21014404296875, -4338355948977389568.0);
        path.lineTo(316.000579833984375, -4338355948977389568.0);
        path.moveTo(354.208984375, -4338355948977389568.0);
        path.lineTo(773.00177001953125, -4338355948977389568.0);
        path.lineTo(1.5069369808623501312e+20, 75180972320904708096.0);
        path.lineTo(1.5069369808623501312e+20, 75180972320904708096.0);
        path.lineTo(354.208984375, -4338355948977389568.0);
        return path;
    },

    // From crbug.com/844873. Hangs repeatedly splitting alternate vertices.
    []() -> RawPath {
        RawPath path;
        path.moveTo(10, -1e+20f);
        path.lineTo(11, 25000);
        path.lineTo(10, 25000);
        path.lineTo(11, 25010);
        return path;
    },

    // Reduction from circular_arcs_stroke_and_fill_round GM which
    // repeatedly splits on the opposite edge from case 34 above.
    []() -> RawPath {
        RawPath path;
        path.moveTo(16.25, 26.495191574096679688);
        path.lineTo(32.420825958251953125, 37.377376556396484375);
        path.lineTo(25.176382064819335938, 39.31851959228515625);
        path.moveTo(20, 20);
        path.lineTo(28.847436904907226562, 37.940830230712890625);
        path.lineTo(25.17638397216796875, 39.31851959228515625);
        return path;
    },

    // Reduction from crbug.com/843135 where an intersection is found
    // below the bottom of both intersected edges.
    []() -> RawPath {
        RawPath path;
        path.moveTo(-2791476679359332352, 2608107002026524672);
        path.lineTo(0, 11.95427703857421875);
        path.lineTo(-2781824066779086848, 2599088532777598976);
        path.lineTo(-7772.6875, 7274);
        return path;
    },

    // Reduction from crbug.com/843135. Exercises a case where an intersection
    // is missed.
    // This causes bad ordering in the active edge list.
    []() -> RawPath {
        RawPath path;
        path.moveTo(-1.0662557646016024569e+23, 9.9621425197286319718e+22);
        path.lineTo(-121806400, 113805032);
        path.lineTo(-120098872, 112209680);
        path.lineTo(6.2832999862817380468e-36, 2.9885697364807128906);
        return path;
    },

    // Reduction from crbug.com/851409. Exercises collinear last vertex.
    []() -> RawPath {
        RawPath path;
        path.moveTo(2072553216, 0);
        path.lineTo(2072553216, 1);
        path.lineTo(2072553472, -13.5);
        path.lineTo(2072553216, 0);
        path.lineTo(2072553472, -6.5);
        return path;
    },

    // Another reduction from crbug.com/851409. Exercises two sequential
    // collinear edges.
    []() -> RawPath {
        RawPath path;
        path.moveTo(2072553216, 0);
        path.lineTo(2072553216, 1);
        path.lineTo(2072553472, -13);
        path.lineTo(2072553216, 0);
        path.lineTo(2072553472, -6);
        path.lineTo(2072553472, -13);
        return path;
    },

    // Reduction from crbug.com/860655. Cause is three collinear edges
    // discovered during
    // sanitize_contours pass, before the vertices have been found coincident.
    []() -> RawPath {
        RawPath path;
        path.moveTo(32572426382475264, -3053391034974208);
        path.lineTo(521289856, -48865776);
        path.lineTo(130322464, -12215873);
        path.moveTo(32572426382475264, -3053391034974208);
        path.lineTo(521289856, -48865776);
        path.lineTo(130322464, -12215873);
        path.moveTo(32572426382475264, -3053391034974208);
        path.lineTo(32114477642022912, -3010462031544320);
        path.lineTo(32111784697528320, -3010209702215680);
        return path;
    },
};

// #if defined(SK_GANESH)

#if 0
// A simple concave path. Test this with a non-invertible matrix.
static RawPath create_path_17()
{
    RawPath path;
    path.moveTo(20, 20);
    path.lineTo(80, 20);
    path.lineTo(30, 30);
    path.lineTo(20, 80);
    return path;
}

// An intersection above the first vertex in the mesh.
// Reduction from http://crbug.com/730687
static RawPath create_path_20()
{
    RawPath path;
    path.moveTo(2822128.5, 235.026336669921875);
    path.lineTo(2819349.25, 235.3623504638671875);
    path.lineTo(-340558688, 23.83478546142578125);
    path.lineTo(-340558752, 25.510419845581054688);
    path.lineTo(-340558720, 27.18605804443359375);
    return path;
}

// An intersection whose result is NaN (due to rounded-to-inf endpoint).
static RawPath create_path_21()
{
    RawPath path;
    path.moveTo(1.7889142061167663539e+38, 39338463358011572224.0);
    path.lineTo(1647.4193115234375, -522.603515625);
    path.lineTo(1677.74560546875, -529.0028076171875);
    path.lineTo(1678.29541015625, -528.7847900390625);
    path.lineTo(1637.5167236328125, -519.79266357421875);
    path.lineTo(1647.4193115234375, -522.603515625);
    return path;
}

// An edge collapse event which also collapses a neighbour, requiring
// its event to be removed.
static RawPath create_path_25()
{
    RawPath path;
    path.moveTo(43.44110107421875, 148.15106201171875);
    path.lineTo(44.64471435546875, 148.16748046875);
    path.lineTo(46.35009765625, 147.403076171875);
    path.lineTo(46.45404052734375, 148.34906005859375);
    path.lineTo(45.0400390625, 148.54205322265625);
    path.lineTo(44.624053955078125, 148.9810791015625);
    path.lineTo(44.59405517578125, 149.16107177734375);
    path.lineTo(44.877044677734375, 149.62005615234375);
    path.lineTo(144.373016357421875, 68.8070068359375);
    return path;
}

// An edge collapse event causes an edge to become collinear, requiring
// its event to be removed.
static RawPath create_path_26()
{
    RawPath path;
    path.moveTo(43.44110107421875, 148.15106201171875);
    path.lineTo(44.64471435546875, 148.16748046875);
    path.lineTo(46.35009765625, 147.403076171875);
    path.lineTo(46.45404052734375, 148.34906005859375);
    path.lineTo(45.0400390625, 148.54205322265625);
    path.lineTo(44.624053955078125, 148.9810791015625);
    path.lineTo(44.59405517578125, 149.16107177734375);
    path.lineTo(44.877044677734375, 149.62005615234375);
    path.lineTo(144.373016357421875, 68.8070068359375);
    return path;
}

// A path which results in non-finite points when stroked and bevelled for AA.
static RawPath create_path_27()
{
    RawPath path;
    path.moveTo(8.5027233009104409507e+37, 1.7503381025241130639e+37);
    path.lineTo(7.0923661737711584874e+37, 1.4600074517285415699e+37);
    path.lineTo(7.0848733446033294691e+37, 1.4584649744781838604e+37);
    path.lineTo(-2.0473916115129349496e+37, -4.2146796450364162012e+36);
    path.lineTo(2.0473912312177548811e+37, 4.2146815465123165435e+36);
    return path;
}

// AA stroking this path produces intersection failures on bevelling.
// This should skip the point, but not assert.
static RawPath create_path_28()
{
    RawPath path;
    path.moveTo(-7.5952312625177475154e+21, -2.6819185100266674911e+24);
    path.lineTo(1260.3787841796875, 1727.7947998046875);
    path.lineTo(1260.5567626953125, 1728.0386962890625);
    path.lineTo(1.1482511310557754163e+21, 4.054538502765980051e+23);
    path.lineTo(-7.5952312625177475154e+21, -2.6819185100266674911e+24);
    return path;
}

#if 0
// A path with vertices which become infinite on AA stroking. Should not crash or assert.
static RawPath create_path_31()
{
    RawPath path;
    path.moveTo(2.0257809259190991347e+36, -1244080640);
    path.conicTo(2.0257809259190991347e+36,
                 -1244080640,
                 2.0257809259190991347e+36,
                 0.10976474732160568237,
                 0.70710676908493041992);
    path.lineTo(-10036566016, -1954718402215936);
    path.conicTo(-1.1375507718551896064e+20,
                 -1954721086570496,
                 10036566016,
                 -1954721086570496,
                 0.70710676908493041992);
    return path;
}
#endif

// Reduction from crbug.com/851914.
static RawPath create_path_38()
{
    RawPath path;
    path.moveTo(14.400531768798828125, 17.711114883422851562);
    path.lineTo(14.621990203857421875, 171563104293879808);
    path.lineTo(14.027951240539550781, 872585759381520384);
    path.lineTo(14.0216827392578125, 872665817571917824);
    path.lineTo(7.699314117431640625, -3417320793833472);
    path.moveTo(11.606547355651855469, 17.40966796875);
    path.lineTo(7642114886926860288, 21.08358001708984375);
    path.lineTo(11.606547355651855469, 21.08358001708984375);
    return path;
}

// Reduction from crbug.com/860453. Tests a case where a "missing" intersection
// requires the active edge list to go out-of-order.
static RawPath create_path_41()
{
    RawPath path;
    path.moveTo(72154931603311689728.0, 330.95965576171875);
    path.lineTo(24053266013925408768.0, 78.11376953125);
    path.lineTo(1.2031099003292404941e+20, 387.168731689453125);
    path.lineTo(68859835992355373056.0, 346.55047607421875);
    path.lineTo(76451708695451009024.0, 337.780029296875);
    path.moveTo(-20815817797613387776.0, 18065700622522384384.0);
    path.lineTo(-72144121204987396096.0, 142.855804443359375);
    path.lineTo(72144121204987396096.0, 325.184783935546875);
    path.lineTo(1.2347242901040791552e+20, 18065700622522384384.0);
    return path;
}

// Reduction from crbug.com/866319. Cause is edges that are collinear when tested from
// one side, but non-collinear when tested from the other.
static RawPath create_path_43()
{
    RawPath path;
    path.moveTo(307316821852160, -28808363114496);
    path.lineTo(307165222928384, -28794154909696);
    path.lineTo(307013691113472, -28779948802048);
    path.lineTo(306862159298560, -28765744791552);
    path.lineTo(306870313025536, -28766508154880);
    path.lineTo(307049695019008, -28783327313920);
    path.lineTo(307408660332544, -28816974020608);
    return path;
}

// Reduction from crbug.com/966696
static RawPath create_path_44()
{
    RawPath path;
    path.moveTo(114.4606170654296875, 186.443878173828125);
    path.lineTo(91.5394744873046875, 185.4189453125);
    path.lineTo(306.45538330078125, 3203.986083984375);
    path.moveTo(16276206965409972224.0, 815.59393310546875);
    path.lineTo(-3.541605062372533207e+20, 487.7236328125);
    path.lineTo(-3.541605062372533207e+20, 168.204071044921875);
    path.lineTo(16276206965409972224.0, 496.07427978515625);
    path.moveTo(-3.541605062372533207e+20, 167.00958251953125);
    path.lineTo(-3.541605062372533207e+20, 488.32086181640625);
    path.lineTo(16276206965409972224.0, 816.78839111328125);
    path.lineTo(16276206965409972224.0, 495.47705078125);
    return path;
}

// Reduction from crbug.com/966274.
static RawPath create_path_45()
{
    RawPath path;
    path.moveTo(706471854080, 379003666432);
    path.lineTo(706503180288, 379020443648);
    path.lineTo(706595717120, 379070087168);
    path.lineTo(706626060288, 379086372864);
    path.lineTo(706656141312, 379102527488);
    path.lineTo(706774171648, 379165835264);
    path.lineTo(706803073024, 379181334528);
    path.lineTo(706831712256, 379196702720);
    path.lineTo(706860154880, 379211939840);
    path.lineTo(706888335360, 379227078656);
    path.lineTo(706916253696, 379242053632);
    path.lineTo(706956820480, 379263811584);
    path.lineTo(706929098752, 379248934912);
    path.lineTo(706901114880, 379233927168);
    path.lineTo(706872934400, 379218821120);
    path.lineTo(706844491776, 379203551232);
    path.lineTo(706815787008, 379188183040);
    path.lineTo(706786885632, 379172651008);
    path.lineTo(706757722112, 379156987904);
    path.lineTo(706728296448, 379141226496);
    path.lineTo(706698608640, 379125301248);
    path.lineTo(706668724224, 379109244928);
    path.lineTo(706638577664, 379093090304);
    path.lineTo(706608168960, 379076771840);
    path.lineTo(706484174848, 379010252800);
    return path;
}

// Reduction from crbug.com/969359. Inf generated by intersections
// causes NaN in subsequent intersections, leading to assert or hang.

static RawPath create_path_46()
{
    RawPath path;
    path.moveTo(1.0321827899075254821e+37, -5.1199920965387697886e+37);
    path.lineTo(-1.0321827899075254821e+37, 5.1199920965387697886e+37);
    path.lineTo(-1.0425214946728668754e+37, 4.5731834042267216669e+37);
    path.moveTo(-9.5077331762291841872e+36, 8.1304868292377430302e+37);
    path.lineTo(9.5077331762291841872e+36, -8.1304868292377430302e+37);
    path.lineTo(1.0795449417808426232e+37, 1.2246856113744539311e+37);
    path.moveTo(-165.8018341064453125, -44.859375);
    path.lineTo(-9.558702871563160835e+36, -7.9814405281448285475e+37);
    path.lineTo(-9.4147814283168490381e+36, -8.3935116522790983488e+37);
    return path;
}

// Reduction from crbug.com/1245359
static RawPath create_path_47()
{
    RawPath path;
    // path.setFillType(SkPathFillType::kWinding);
    path.moveTo(SkBits2Float(0xdfb80000), SkBits2Float(0x4cb9b4a5)); // -2.65172e+19f,  9.73632e+07f
    path.lineTo(SkBits2Float(0xdfb80000), SkBits2Float(0xe396b530)); // -2.65172e+19f, -5.56014e+21f
    path.lineTo(SkBits2Float(0x5fb80000), SkBits2Float(0xe396b530)); //  2.65172e+19f, -5.56014e+21f
    path.lineTo(SkBits2Float(0x5fb80000), SkBits2Float(0x6396b530)); //  2.65172e+19f,  5.56014e+21f
    path.lineTo(SkBits2Float(0x4cc07742), SkBits2Float(0x6396b530)); //  1.00908e+08f,  5.56014e+21f
    path.lineTo(SkBits2Float(0xdfb80000), SkBits2Float(0x6396b530)); // -2.65172e+19f,  5.56014e+21f
    path.lineTo(SkBits2Float(0xdfb80000), SkBits2Float(0xe396b530)); // -2.65172e+19f, -5.56014e+21f
    path.lineTo(SkBits2Float(0x4cc07742), SkBits2Float(0xe396b530)); //  1.00908e+08f, -5.56014e+21f
    path.lineTo(SkBits2Float(0x4cc079c8), SkBits2Float(0xe396b530)); //  1.00913e+08f, -5.56014e+21f
    path.lineTo(SkBits2Float(0x4cc079c8), SkBits2Float(0x4cb9b4a5)); //  1.00913e+08f,  9.73632e+07f
    path.lineTo(SkBits2Float(0xdfb80000), SkBits2Float(0x4cb9b4a5)); // -2.65172e+19f,  9.73632e+07f
    path.lineTo(SkBits2Float(0xdfb80000), SkBits2Float(0x4cb74d74)); // -2.65172e+19f,  9.61033e+07f
    path.lineTo(SkBits2Float(0x4cc079c8), SkBits2Float(0x4cb74d74)); //  1.00913e+08f,  9.61033e+07f
    path.lineTo(SkBits2Float(0x4cc079c8), SkBits2Float(0x6396b530)); //  1.00913e+08f,  5.56014e+21f
    path.lineTo(SkBits2Float(0x4cc07742), SkBits2Float(0x6396b530)); //  1.00908e+08f,  5.56014e+21f
    path.lineTo(SkBits2Float(0x4cc07742), SkBits2Float(0x4cb74d74)); //  1.00908e+08f,  9.61033e+07f
    path.lineTo(SkBits2Float(0x5fb80000), SkBits2Float(0x4cb74d74)); //  2.65172e+19f,  9.61033e+07f
    path.lineTo(SkBits2Float(0x5fb80000), SkBits2Float(0x6396b530)); //  2.65172e+19f,  5.56014e+21f
    path.lineTo(SkBits2Float(0xdfb80000), SkBits2Float(0x6396b530)); // -2.65172e+19f,  5.56014e+21f
    path.lineTo(SkBits2Float(0xdfb80000), SkBits2Float(0x4cb9b4a5)); // -2.65172e+19f,  9.73632e+07f
    path.close();

    path.moveTo(SkBits2Float(0xdfb39e51), SkBits2Float(0xe282c5bd)); // -2.58857e+19f, -1.20616e+21f
    path.lineTo(SkBits2Float(0xdf8a47ec), SkBits2Float(0xe3b90de5)); // -1.99284e+19f, -6.8273e+21f
    path.lineTo(SkBits2Float(0x5eb8b548), SkBits2Float(0xe391e278)); //  6.65481e+18f, -5.38219e+21f
    path.lineTo(SkBits2Float(0x5e9c5925), SkBits2Float(0xe39344a0)); //  5.63304e+18f, -5.43323e+21f
    path.lineTo(SkBits2Float(0x5e6ead5a), SkBits2Float(0xe394b6a4)); //  4.29963e+18f, -5.48656e+21f
    path.lineTo(SkBits2Float(0x5e694ef2), SkBits2Float(0xe394cd7f)); //  4.20291e+18f, -5.48985e+21f
    path.lineTo(SkBits2Float(0x5e669614), SkBits2Float(0xe394d8e2)); //  4.15387e+18f, -5.49149e+21f
    path.lineTo(SkBits2Float(0x5e63d6a7), SkBits2Float(0xe394e43c)); //  4.10437e+18f, -5.49313e+21f
    path.lineTo(SkBits2Float(0x5e5e43cb), SkBits2Float(0xe394fad6)); //  4.00397e+18f, -5.49639e+21f
    path.lineTo(SkBits2Float(0x5e5895ab), SkBits2Float(0xe3951148)); //  3.90164e+18f, -5.49962e+21f
    path.lineTo(SkBits2Float(0x5e52cb8e), SkBits2Float(0xe395278b)); //  3.79735e+18f, -5.50283e+21f
    path.lineTo(SkBits2Float(0x5e4fdbc5), SkBits2Float(0xe395329a)); //  3.74445e+18f, -5.50442e+21f
    path.lineTo(SkBits2Float(0x5e4fdbc5), SkBits2Float(0xe395329a)); //  3.74445e+18f, -5.50442e+21f
    path.lineTo(SkBits2Float(0x5e4fdbc5), SkBits2Float(0xe395329a)); //  3.74445e+18f, -5.50442e+21f
    path.lineTo(SkBits2Float(0x5e4fdbc5), SkBits2Float(0xe395329a)); //  3.74445e+18f, -5.50442e+21f
    path.lineTo(SkBits2Float(0x5e4fdbc5), SkBits2Float(0xe395329a)); //  3.74445e+18f, -5.50442e+21f
    path.lineTo(SkBits2Float(0x5e4fdbc5), SkBits2Float(0xe395329a)); //  3.74445e+18f, -5.50442e+21f
    path.lineTo(SkBits2Float(0x5e4fdbc5), SkBits2Float(0xe395329a)); //  3.74445e+18f, -5.50442e+21f
    path.lineTo(SkBits2Float(0x5e4fdbc5), SkBits2Float(0xe395329a)); //  3.74445e+18f, -5.50442e+21f
    path.lineTo(SkBits2Float(0x5e4fdbc5), SkBits2Float(0xe395329a)); //  3.74445e+18f, -5.50442e+21f
    path.lineTo(SkBits2Float(0x5e4fdbc5), SkBits2Float(0xe395329a)); //  3.74445e+18f, -5.50442e+21f
    path.lineTo(SkBits2Float(0xdfb80000), SkBits2Float(0xe396b530)); // -2.65172e+19f, -5.56014e+21f
    path.lineTo(SkBits2Float(0x5fb80000), SkBits2Float(0xe396b530)); //  2.65172e+19f, -5.56014e+21f
    path.lineTo(SkBits2Float(0x5fb80000), SkBits2Float(0x4cc8d35d)); //  2.65172e+19f,  1.0529e+08f
    path.lineTo(SkBits2Float(0xdfe2ba48), SkBits2Float(0x63512f2f)); // -3.26749e+19f,  3.85877e+21f
    path.lineTo(SkBits2Float(0xdf7f64f6), SkBits2Float(0xe3b9b457)); // -1.84031e+19f, -6.85129e+21f
    path.lineTo(SkBits2Float(0xdfb80000), SkBits2Float(0x4cc8d35d)); // -2.65172e+19f,  1.0529e+08f
    path.lineTo(SkBits2Float(0xdfb80000), SkBits2Float(0x4cbbf2a2)); // -2.65172e+19f,  9.85388e+07f
    path.lineTo(SkBits2Float(0x4cc079c8), SkBits2Float(0x4cbbf2a2)); //  1.00913e+08f,  9.85388e+07f
    path.lineTo(SkBits2Float(0x4cc079c8), SkBits2Float(0x6396b530)); //  1.00913e+08f,  5.56014e+21f
    path.lineTo(SkBits2Float(0x4cc07742), SkBits2Float(0x6396b530)); //  1.00908e+08f,  5.56014e+21f
    path.lineTo(SkBits2Float(0x4cc07742), SkBits2Float(0x4cbbf2a2)); //  1.00908e+08f,  9.85388e+07f
    path.lineTo(SkBits2Float(0x5fb80000), SkBits2Float(0x4cbbf2a2)); //  2.65172e+19f,  9.85388e+07f
    path.lineTo(SkBits2Float(0xdeb8b548), SkBits2Float(0x6391e278)); // -6.65481e+18f,  5.38219e+21f
    path.lineTo(SkBits2Float(0x4cc07488), SkBits2Float(0x4ccb2302)); //  1.00902e+08f,  1.06502e+08f
    path.lineTo(SkBits2Float(0x5fb39e51), SkBits2Float(0x6282c5bd)); //  2.58857e+19f,  1.20616e+21f
    path.lineTo(SkBits2Float(0x5fb39e51), SkBits2Float(0x6282c5bd)); //  2.58857e+19f,  1.20616e+21f
    path.lineTo(SkBits2Float(0x5f8bb406), SkBits2Float(0x63b3cfe4)); //  2.01334e+19f,  6.63389e+21f
    path.lineTo(SkBits2Float(0xdfdb889b), SkBits2Float(0x6364da0b)); // -3.16381e+19f,  4.22157e+21f
    path.lineTo(SkBits2Float(0xdfb39e51), SkBits2Float(0xe282c5bd)); // -2.58857e+19f, -1.20616e+21f
    path.close();
    return path;
}

static std::unique_ptr<GrFragmentProcessor> create_linear_gradient_processor(
    GrRecordingContext* rContext,
    const SkMatrix& ctm)
{
    Vec2D pts[2] = {{0, 0}, {1, 1}};
    SkColor colors[2] = {SK_ColorGREEN, SK_ColorBLUE};
    sk_sp<SkShader> shader =
        SkGradientShader::MakeLinear(pts, colors, nullptr, std::size(colors), SkTileMode::kClamp);
    GrColorInfo colorInfo(GrColorType::kRGBA_8888, kPremul_SkAlphaType, nullptr);
    SkSurfaceProps props; // default props for testing
    return GrFragmentProcessors::Make(shader.get(), {rContext, &colorInfo, props}, ctm);
}

static void test_path(GrRecordingContext* rContext,
                      skgpu::ganesh::SurfaceDrawContext* sdc,
                      const RawPath& path,
                      const SkMatrix& matrix = SkMatrix::I(),
                      GrAAType aaType = GrAAType::kNone,
                      std::unique_ptr<GrFragmentProcessor> fp = nullptr)
{
    skgpu::ganesh::TriangulatingPathRenderer pr;
    pr.setMaxVerbCount(100);

    GrPaint paint;
    paint.setXPFactory(GrPorterDuffXPFactory::Get(SkBlendMode::kSrc));
    if (fp)
    {
        paint.setColorFragmentProcessor(std::move(fp));
    }

    SkIRect clipConservativeBounds = SkIRect::MakeWH(sdc->width(), sdc->height());
    GrStyle style(SkStrokeRec::kFill_InitStyle);
    GrStyledShape shape(path, style);
    skgpu::ganesh::PathRenderer::DrawPathArgs args{rContext,
                                                   std::move(paint),
                                                   &GrUserStencilSettings::kUnused,
                                                   sdc,
                                                   nullptr,
                                                   &clipConservativeBounds,
                                                   &matrix,
                                                   &shape,
                                                   aaType,
                                                   false};
    pr.drawPath(args);
}

DEF_GANESH_TEST_FOR_ALL_CONTEXTS(TriangulatingPathRendererTests,
                                 reporter,
                                 ctxInfo,
                                 CtsEnforcement::kNever)
{
    auto ctx = ctxInfo.directContext();
    auto sdc = skgpu::ganesh::SurfaceDrawContext::Make(ctx,
                                                       GrColorType::kRGBA_8888,
                                                       nullptr,
                                                       SkBackingFit::kApprox,
                                                       {800, 800},
                                                       SkSurfaceProps(),
                                                       /*label=*/{},
                                                       1,
                                                       GrMipmapped::kNo,
                                                       GrProtected::kNo,
                                                       kTopLeft_GrSurfaceOrigin);
    if (!sdc)
    {
        return;
    }

    ctx->flushAndSubmit();
    // Adding discard to appease vulkan validation warning about loading uninitialized data on draw
    sdc->discard();

    for (CreatePathFn createPath : kNonEdgeAAPaths)
    {
        test_path(ctx, sdc.get(), createPath());
    }
    SkMatrix nonInvertibleMatrix = SkMatrix::Scale(0, 0);
    std::unique_ptr<GrFragmentProcessor> fp(create_linear_gradient_processor(ctx, SkMatrix()));
    test_path(ctx,
              sdc.get(),
              create_path_17(),
              nonInvertibleMatrix,
              GrAAType::kCoverage,
              std::move(fp));
    test_path(ctx, sdc.get(), create_path_20(), SkMatrix(), GrAAType::kCoverage);
    test_path(ctx, sdc.get(), create_path_21(), SkMatrix(), GrAAType::kCoverage);
    test_path(ctx, sdc.get(), create_path_25(), SkMatrix(), GrAAType::kCoverage);
    test_path(ctx, sdc.get(), create_path_26(), SkMatrix(), GrAAType::kCoverage);
    test_path(ctx, sdc.get(), create_path_27(), SkMatrix(), GrAAType::kCoverage);
    test_path(ctx, sdc.get(), create_path_28(), SkMatrix(), GrAAType::kCoverage);
#if 0
    test_path(ctx, sdc.get(), create_path_31(), SkMatrix(), GrAAType::kCoverage);
#endif
    test_path(ctx, sdc.get(), create_path_38(), SkMatrix(), GrAAType::kCoverage);
    test_path(ctx, sdc.get(), create_path_41(), SkMatrix(), GrAAType::kCoverage);
    test_path(ctx, sdc.get(), create_path_43(), SkMatrix(), GrAAType::kCoverage);
    test_path(ctx, sdc.get(), create_path_44(), SkMatrix(), GrAAType::kCoverage);
    test_path(ctx, sdc.get(), create_path_45(), SkMatrix(), GrAAType::kCoverage);
    test_path(ctx, sdc.get(), create_path_46(), SkMatrix(), GrAAType::kCoverage);
    test_path(ctx, sdc.get(), create_path_47(), SkMatrix(), GrAAType::kCoverage);
}
#endif

// #endif // defined(SK_GANESH)

namespace
{

#if 0
class SimplerVertexAllocator : public GrEagerVertexAllocator
{
public:
    void* lock(size_t stride, int eagerCount) override
    {
        size_t allocSize = eagerCount * stride;
        if (allocSize > fVertexAllocSize)
        {
            fVertexData.reset(allocSize);
        }
        return fVertexData;
    }

    void unlock(int) override {}

    AutoTMalloc<char> fVertexData;
    size_t fVertexAllocSize = 0;
};
#endif

} // namespace

struct Edge
{
    Edge reverse() const { return {fP1, fP0}; }
    Vec2D fP0, fP1;
};

static bool operator<(const Edge& a, const Edge& b)
{
    if (a.fP0.x != b.fP0.x)
    {
        return a.fP0.x < b.fP0.x;
    }
    if (a.fP0.y != b.fP0.y)
    {
        return a.fP0.y < b.fP0.y;
    }
    if (a.fP1.x != b.fP1.x)
    {
        return a.fP1.x < b.fP1.x;
    }
    if (a.fP1.y != b.fP1.y)
    {
        return a.fP1.y < b.fP1.y;
    }
    return false;
}

using EdgeMap = std::map<Edge, int>;

static void add_edge(EdgeMap& edgeMap, Vec2D p0, Vec2D p1)
{
    if (p0 == p1)
    {
        return;
    }
    Edge edge{p0, p1};
    // First check if this edge already exists in reverse.
    auto reverseIter = edgeMap.find(edge.reverse());
    if (reverseIter != edgeMap.end())
    {
        --reverseIter->second;
    }
    else
    {
        ++edgeMap[edge];
    }
}

static void add_tri_edges(EdgeMap& edgeMap, const Vec2D pts[3])
{
    for (int i = 0; i < 3; ++i)
    {
        Vec2D p0 = pts[i], p1 = pts[(i + 1) % 3];
        // The triangulator shouldn't output degenerate triangles.
        CHECK(p0 != p1);
        add_edge(edgeMap, p0, p1);
    }
}

static EdgeMap simplify(const EdgeMap& edges, FillRule fillType)
{
    // Prune out the edges whose count went to zero, and reverse the edges whose
    // count is negative.
    EdgeMap simplifiedEdges;
    for (auto [edge, count] : edges)
    {
        // We should only have one ordering of any given edge.
        assert(edges.find(edge.reverse()) == edges.end());
        if (fillType == FillRule::evenOdd)
        {
            count = abs(count) & 1;
        }
        if (count > 0)
        {
            simplifiedEdges[edge] = count;
        }
        else if (count < 0)
        {
            simplifiedEdges[edge.reverse()] = -count;
        }
    }
    return simplifiedEdges;
}

static bool isfinite(Vec2D p)
{
    return std::isfinite(p.x) && std::isfinite(p.y);
}

static void verify_simple_inner_polygons(const char* shapeName,
                                         const RawPath& path)
{
    for (auto fillType : {FillRule::nonZero})
    {
        size_t lastVertexCount = 0;
        for (int faceOrdering = 0; faceOrdering < 4; ++faceOrdering)
        {
            // path.setFillType(fillType);
            TrivialBlockAllocator alloc(GrTriangulator::kArenaDefaultChunkSize);
            GrInnerFanTriangulator triangulator(
                path,
                Mat2D(),
                path.bounds().width() > path.bounds().height()
                    ? GrTriangulator::Comparator::Direction::kHorizontal
                    : GrTriangulator::Comparator::Direction::kVertical,
                fillType,
                &alloc);
            int pathID = rand() & 0xffff;
            std::vector<gpu::TriangleVertex> vertexData(
                triangulator.maxVertexCount());
            size_t vertexCount;
            switch (faceOrdering)
            {
                case 0:
                {
                    gpu::WriteOnlyMappedMemory<gpu::TriangleVertex>
                        mappedMemory(vertexData.data(),
                                     triangulator.maxVertexCount());
                    vertexCount =
                        triangulator.polysToTriangles(pathID,
                                                      gpu::WindingFaces::all,
                                                      &mappedMemory);
                    CHECK(mappedMemory.elementsWritten() == vertexCount);
                    lastVertexCount = vertexCount;
                    break;
                }
                case 1:
                {
                    assert(lastVertexCount <= triangulator.maxVertexCount());
                    gpu::WriteOnlyMappedMemory<gpu::TriangleVertex>
                        mappedMemory(vertexData.data(), lastVertexCount);
                    vertexCount = triangulator.polysToTriangles(
                        pathID,
                        gpu::WindingFaces::negative,
                        &mappedMemory);
                    vertexCount += triangulator.polysToTriangles(
                        pathID,
                        gpu::WindingFaces::positive,
                        &mappedMemory);
                    CHECK(vertexCount == lastVertexCount);
                    CHECK(!mappedMemory.hasRoomFor(1));
                    break;
                }
                case 2:
                {
                    assert(lastVertexCount <= triangulator.maxVertexCount());
                    gpu::WriteOnlyMappedMemory<gpu::TriangleVertex>
                        mappedMemory(vertexData.data(), lastVertexCount);
                    vertexCount = triangulator.polysToTriangles(
                        pathID,
                        gpu::WindingFaces::positive,
                        &mappedMemory);
                    vertexCount += triangulator.polysToTriangles(
                        pathID,
                        gpu::WindingFaces::negative,
                        &mappedMemory);
                    CHECK(vertexCount == lastVertexCount);
                    CHECK(!mappedMemory.hasRoomFor(1));
                    break;
                }
                case 3:
                {
                    assert(lastVertexCount <= triangulator.maxVertexCount());
                    gpu::WriteOnlyMappedMemory<gpu::TriangleVertex>
                        mappedMemory(vertexData.data(), lastVertexCount);
                    vertexCount = triangulator.polysToTriangles(
                        pathID,
                        gpu::WindingFaces::positive,
                        &mappedMemory);
                    vertexCount += triangulator.polysToTriangles(
                        pathID,
                        gpu::WindingFaces::negative,
                        &mappedMemory);
                    CHECK(vertexCount == lastVertexCount);
                    CHECK(!mappedMemory.hasRoomFor(1));
                    break;
                }
            }
            const gpu::TriangleVertex* tris = vertexData.data();
            const GrInnerFanTriangulator::GroutTriangleList& grouts =
                triangulator.groutList();

            // Count up all the triangulated edges.
            EdgeMap trianglePlusGroutEdges;
            for (size_t i = 0; i < vertexCount; i += 3)
            {
                int plsWeight = tris[i].testing_weight_pathID() >> 16;
                uint16_t plsID = tris[i].testing_weight_pathID();
                assert(tris[i + 1].testing_weight_pathID() ==
                       tris[i].testing_weight_pathID());
                assert(tris[i + 2].testing_weight_pathID() ==
                       tris[i].testing_weight_pathID());
                Vec2D pts[3] = {tris[i].testing_point(),
                                tris[i + 1].testing_point(),
                                tris[i + 2].testing_point()};
                if (plsWeight < 0)
                {
                    std::swap(pts[0], pts[1]);
                }
                for (int i = 0; i < abs(plsWeight); ++i)
                {
                    add_tri_edges(trianglePlusGroutEdges, pts);
                }
                CHECK(plsID == pathID);
            }
            // Count up all the grout edges.
            int groutCount = 0;
            for (const auto* node = grouts.head(); node; node = node->fNext)
            {
                add_tri_edges(trianglePlusGroutEdges, node->fPts);
                ++groutCount;
            }
            CHECK(groutCount == grouts.count());
            // The triangulated + grout edges should cancel out to the inner
            // polygon edges.
            trianglePlusGroutEdges = simplify(trianglePlusGroutEdges, fillType);

            // Build the inner polygon edges.
            EdgeMap innerFanEdges;
            Vec2D startPoint{}, lastPoint{};
            bool hasStartPoint = false;
            for (auto [verb, pts] : path)
            {
                switch (verb)
                {
                    case PathVerb::move:
                        if (hasStartPoint)
                        {
                            add_edge(innerFanEdges, lastPoint, startPoint);
                        }
                        if (isfinite(pts[0]))
                        {
                            lastPoint = startPoint = pts[0];
                            hasStartPoint = true;
                        }
                        else
                        {
                            hasStartPoint = false;
                        }
                        break;
                    case PathVerb::close:
                        if (hasStartPoint)
                        {
                            add_edge(innerFanEdges, lastPoint, startPoint);
                            lastPoint = startPoint;
                        }
                        break;
                    case PathVerb::line:
                        if (!isfinite(pts[1]))
                        {
                            break;
                        }
                        if (hasStartPoint)
                        {
                            add_edge(innerFanEdges, lastPoint, pts[1]);
                            lastPoint = pts[1];
                        }
                        else
                        {
                            startPoint = lastPoint = pts[1];
                            hasStartPoint = true;
                        }
                        break;
                    case PathVerb::quad:
                    case PathVerb::cubic:
                        RIVE_UNREACHABLE();
                }
            }
            add_edge(innerFanEdges, lastPoint, startPoint);
            innerFanEdges = simplify(innerFanEdges, fillType);

            // The triangulated + grout edges should cancel out to the inner
            // polygon edges. First verify that every inner polygon edge can be
            // found in the triangulation.
            for (auto [edge, count] : innerFanEdges)
            {
                auto it = trianglePlusGroutEdges.find(edge);
                if (it != trianglePlusGroutEdges.end())
                {
                    it->second -= count;
                    if (it->second == 0)
                    {
                        trianglePlusGroutEdges.erase(it);
                    }
                    continue;
                }
                it = trianglePlusGroutEdges.find(edge.reverse());
                if (it != trianglePlusGroutEdges.end())
                {
                    it->second += count;
                    if (it->second == 0)
                    {
                        trianglePlusGroutEdges.erase(it);
                    }
                    continue;
                }
                printf("error: %s: edge [%g,%g]:[%g,%g] not found in "
                       "triangulation.",
                       shapeName,
                       edge.fP0.x,
                       edge.fP0.y,
                       edge.fP1.x,
                       edge.fP1.y);
                FAIL();
                return;
            }
            // Now verify that there are no spurious edges in the triangulation.
            //
            // NOTE: The triangulator's definition of wind isn't always correct
            // for edges that run exactly parallel to the sweep (either vertical
            // or horizontal edges). This doesn't actually matter though because
            // T-junction artifacts don't happen on axis-aligned edges. Tolerate
            // spurious edges that (1) come in pairs of 2, and (2) are either
            // exactly horizontal or exactly vertical exclusively.
            bool hasSpuriousHorz = false, hasSpuriousVert = false;
            for (auto [edge, count] : trianglePlusGroutEdges)
            {
                if (count % 2 == 0)
                {
                    if (edge.fP0.x == edge.fP1.x && !hasSpuriousVert)
                    {
                        hasSpuriousHorz = true;
                        continue;
                    }
                    if (edge.fP0.y == edge.fP1.y && !hasSpuriousHorz)
                    {
                        hasSpuriousVert = true;
                        continue;
                    }
                }
                printf("error: %s: spurious edge [%g,%g]:[%g,%g] found in "
                       "triangulation.",
                       shapeName,
                       edge.fP0.x,
                       edge.fP0.y,
                       edge.fP1.x,
                       edge.fP1.y);
                FAIL();
                return;
            }
        }
    }
}

class TestPath : public RawPath
{
public:
    TestPath& moveTo(float x, float y)
    {
        RawPath::moveTo(x, y);
        return *this;
    }
    TestPath& lineTo(float x, float y)
    {
        RawPath::lineTo(x, y);
        return *this;
    }
    TestPath& close()
    {
        RawPath::close();
        return *this;
    }
};

static float frand() { return rand() / static_cast<float>(RAND_MAX); }

namespace ToolUtils
{
RawPath make_star(float sx, float sy, int numPts = 5, int step = 2)
{
    assert(numPts != step);
    RawPath path;
    path.moveTo(0, -1);
    for (int i = 1; i < numPts; ++i)
    {
        int idx = i * step % numPts;
        float theta = idx * 2 * math::PI / numPts + math::PI / 2;
        float x = cosf(theta);
        float y = -sinf(theta);
        path.lineTo(x, y);
    }
    path.transform(Mat2D::fromScale(sx, sy));
    return path;
}
} // namespace ToolUtils

TEST_CASE("GrInnerFanTriangulator", "[triangulator]")
{
    verify_simple_inner_polygons("simple triangle",
                                 TestPath().lineTo(1, 0).lineTo(0, 1));
    verify_simple_inner_polygons(
        "simple square",
        TestPath().lineTo(1, 0).lineTo(1, 1).lineTo(0, 1));
    verify_simple_inner_polygons(
        "concave polygon",
        TestPath().lineTo(1, 0).lineTo(.5f, .5f).lineTo(1, 1).lineTo(0, 1));
    verify_simple_inner_polygons(

        "double wound triangle",
        TestPath().lineTo(1, 0).lineTo(0, 1).lineTo(0, 0).lineTo(1, 0).lineTo(
            0,
            1));
    verify_simple_inner_polygons(
        "self-intersecting bowtie",
        TestPath().lineTo(1, 0).lineTo(0, 1).lineTo(1, 1));
    verify_simple_inner_polygons(
        "asymmetrical bowtie",
        TestPath().lineTo(1, 0).lineTo(0, 1).lineTo(.1f, -.1f));
    verify_simple_inner_polygons(
        "bowtie with extremely small section",
        TestPath().lineTo(1, 0).lineTo(0, 1).lineTo(1e-6f, -1e-6f));
    verify_simple_inner_polygons("intersecting squares",
                                 TestPath()
                                     .lineTo(1, 0)
                                     .lineTo(1, 1)
                                     .lineTo(0, 1)
                                     .moveTo(.5f, .5f)
                                     .lineTo(1.5f, .5f)
                                     .lineTo(1.5f, 1.5f)
                                     .lineTo(.5f, 1.5f)
                                     .close());
    verify_simple_inner_polygons(

        "6-point \"Star of David\"",
        TestPath()
            .moveTo(cosf(-math::PI / 3), sinf(-math::PI / 3))
            .lineTo(cosf(math::PI / 3), sinf(math::PI / 3))
            .lineTo(cosf(math::PI), sinf(math::PI))
            .moveTo(cosf(0), sinf(0))
            .lineTo(cosf(2 * math::PI / 3), sinf(2 * math::PI / 3))
            .lineTo(cosf(-2 * math::PI / 3), sinf(-2 * math::PI / 3)));
    verify_simple_inner_polygons(

        "double wound \"Star of David\"",
        TestPath()
            .moveTo(cosf(-math::PI / 3), sinf(-math::PI / 3))
            .lineTo(cosf(math::PI / 3), sinf(math::PI / 3))
            .lineTo(cosf(math::PI), sinf(math::PI))
            .lineTo(cosf(-math::PI / 3), sinf(-math::PI / 3))
            .lineTo(cosf(math::PI / 3), sinf(math::PI / 3))
            .lineTo(cosf(math::PI), sinf(math::PI))
            .moveTo(cosf(0), sinf(0))
            .lineTo(cosf(2 * math::PI / 3), sinf(2 * math::PI / 3))
            .lineTo(cosf(-2 * math::PI / 3), sinf(-2 * math::PI / 3)));
    verify_simple_inner_polygons("5-point star",
                                 ToolUtils::make_star(100, 200));
    verify_simple_inner_polygons("\"pointy\" intersecting triangles",
                                 TestPath()
                                     .moveTo(0, -100)
                                     .lineTo(-1e-6f, 100)
                                     .lineTo(1e-6f, 100)
                                     .moveTo(-100, 0)
                                     .lineTo(100, 1e-6f)
                                     .lineTo(100, -1e-6f));
    verify_simple_inner_polygons(
        "overlapping rects with vertical collinear edges",
        TestPath()
            .moveTo(0, 0)
            .lineTo(0, 2)
            .lineTo(1, 2)
            .lineTo(1, 0)
            .moveTo(0, 1)
            .lineTo(0, 3)
            .lineTo(1, 3)
            .lineTo(1, 1));
    verify_simple_inner_polygons(
        "overlapping rects with horizontal collinear edges",
        TestPath()
            .lineTo(2, 0)
            .lineTo(2, 1)
            .lineTo(0, 1)
            .moveTo(1, 0)
            .lineTo(3, 0)
            .lineTo(3, 1)
            .lineTo(1, 1)
            .close());
    for (int i = 0; i < (int)std::size(kNonEdgeAAPaths); ++i)
    {
        std::ostringstream s;
        s << "kNonEdgeAAPaths[" << i << "]";
        verify_simple_inner_polygons(s.str().c_str(), kNonEdgeAAPaths[i]());
    }
    for (int i = 0; i < 50; ++i)
    {
        auto randomPath = TestPath().moveTo(frand(), frand());
        for (int j = 0; j < i; ++j)
        {
            randomPath.lineTo(frand(), frand());
        }
        std::ostringstream s;
        s << "random_path_" << i;
        verify_simple_inner_polygons(s.str().c_str(), randomPath);
    }
}

// Check that the triangulator throws away nonfinite points without crashing or
// asserting.
TEST_CASE("nan-triangulator-path", "[triangulator]")
{
    float nan = std::numeric_limits<float>::quiet_NaN();
    RawPath path;
    path.moveTo(0.000000f, 0.000000f);
    path.lineTo(46.938213f, 12.517612f);
    path.lineTo(68.939590f, 24.927244f);
    path.lineTo(72.996719f, 42.455696f);
    path.moveTo(18.625282f, 25.591682f);
    path.lineTo(nan, 43.069065f);
    path.moveTo(98.432007f, 97.606140f);
    path.lineTo(47.198936f, nan);
    path.lineTo(25.263794f, nan);
    path.lineTo(27.249695f, nan);
    path.lineTo(47.779770f, nan);
    path.moveTo(69.691299f, 18.081133f);
    path.lineTo(60.939247f, 45.603207f);
    path.moveTo(99.137665f, 63.649910f);
    path.lineTo(11.513399f, nan);
    path.lineTo(70.803024f, 4.229769f);
    path.lineTo(55.893333f, 84.540161f);
    path.moveTo(nan, nan);
    path.moveTo(nan, nan);
    path.moveTo(nan, nan);
    path.close();
    path.close();
    path.moveTo(nan, nan);
    path.close();
    path.moveTo(nan, nan);
    path.lineTo(46.938213f, 12.517612f);
    path.moveTo(nan, 1);
    path.moveTo(nan, 1);
    path.moveTo(nan, 1);
    path.close();
    path.close();
    path.moveTo(nan, 1);
    path.close();
    path.moveTo(nan, 1);
    path.lineTo(46.938213f, 12.517612f);
    path.moveTo(1, nan);
    path.moveTo(1, nan);
    path.moveTo(1, nan);
    path.close();
    path.close();
    path.moveTo(1, nan);
    path.close();
    path.moveTo(1, nan);
    path.lineTo(46.938213f, 12.517612f);
    verify_simple_inner_polygons("nan-path", path);
    path.moveTo(1, nan);
    path.moveTo(nan, 1);
    path.moveTo(1, nan);
    path.close();
    path.close();
    path.moveTo(nan, 1);
    path.close();
    path.moveTo(1, nan);
    path.lineTo(46.938213f, 12.517612f);
    verify_simple_inner_polygons("nan-path", path);
}

#if 0
static void test_crbug_1262444(skiatest::Reporter* r)
{
    RawPath path;

    path.setFillType(SkPathFillType::kWinding);
    path.moveTo(SkBits2Float(0x3fe0633f), SkBits2Float(0x3d04a60d)); // 1.75303f, 0.0323849f
    path.cubicTo(
        SkBits2Float(0x3fe27540),
        SkBits2Float(0x3dff593f),
        SkBits2Float(0x3fe45241),
        SkBits2Float(0x3e5e2fbb),
        SkBits2Float(0x3fe55b41),
        SkBits2Float(0x3e9e596d)); // 1.7692f, 0.124682f, 1.78376f, 0.216979f, 1.79185f, 0.309276f
    path.cubicTo(
        SkBits2Float(0x3fe5fa41),
        SkBits2Float(0x3eb3e79c),
        SkBits2Float(0x3fe62f41),
        SkBits2Float(0x3ec975cb),
        SkBits2Float(0x3fe69941),
        SkBits2Float(0x3edfd837)); // 1.7967f, 0.351376f, 1.79832f, 0.393477f, 1.80155f, 0.437196f
    path.cubicTo(
        SkBits2Float(0x3fe70341),
        SkBits2Float(0x3f064e87),
        SkBits2Float(0x3fe6ce41),
        SkBits2Float(0x3f1cb0f2),
        SkBits2Float(0x3fe59041),
        SkBits2Float(0x3f33135e)); // 1.80479f, 0.524636f, 1.80317f, 0.612075f, 1.79346f, 0.699514f
    path.cubicTo(
        SkBits2Float(0x3fe48740),
        SkBits2Float(0x3f468ef5),
        SkBits2Float(0x3fe2df40),
        SkBits2Float(0x3f59a06d),
        SkBits2Float(0x3fe02e3f),
        SkBits2Float(0x3f6cb1e6)); // 1.78538f, 0.775619f, 1.77244f, 0.850104f, 1.75141f, 0.92459f
    path.cubicTo(
        SkBits2Float(0x3fde863f),
        SkBits2Float(0x3f78b759),
        SkBits2Float(0x3fdc743e),
        SkBits2Float(0x3f822957),
        SkBits2Float(0x3fd9c33e),
        SkBits2Float(0x3f87f701)); // 1.73847f, 0.971548f, 1.7223f, 1.01689f, 1.70127f, 1.06223f
    path.cubicTo(
        SkBits2Float(0x3fd98e3e),
        SkBits2Float(0x3f88611f),
        SkBits2Float(0x3fd9593e),
        SkBits2Float(0x3f88cb3e),
        SkBits2Float(0x3fd9243d),
        SkBits2Float(0x3f896a6b)); // 1.69965f, 1.06546f, 1.69804f, 1.0687f, 1.69642f, 1.07356f
    path.cubicTo(
        SkBits2Float(0x3fd63e3c),
        SkBits2Float(0x3f8fa234),
        SkBits2Float(0x3fd2ee3b),
        SkBits2Float(0x3f95d9fd),
        SkBits2Float(0x3fd2ee3b),
        SkBits2Float(0x3f9ce602)); // 1.67377f, 1.12214f, 1.6479f, 1.17071f, 1.6479f, 1.22577f
    path.cubicTo(
        SkBits2Float(0x3fd3233b),
        SkBits2Float(0x3f9cb0f3),
        SkBits2Float(0x3fd3583b),
        SkBits2Float(0x3f9cb0f3),
        SkBits2Float(0x3fd3c23c),
        SkBits2Float(0x3f9c7be4)); // 1.64951f, 1.22415f, 1.65113f, 1.22415f, 1.65437f, 1.22253f
    path.cubicTo(
        SkBits2Float(0x3fd3c23c),
        SkBits2Float(0x3f9cb0f3),
        SkBits2Float(0x3fd3c23c),
        SkBits2Float(0x3f9cb0f3),
        SkBits2Float(0x3fd3c23c),
        SkBits2Float(0x3f9ce602)); // 1.65437f, 1.22415f, 1.65437f, 1.22415f, 1.65437f, 1.22577f
    path.cubicTo(
        SkBits2Float(0x3fd5353c),
        SkBits2Float(0x3f9c46d4),
        SkBits2Float(0x3fd6dd3d),
        SkBits2Float(0x3f9bdcb6),
        SkBits2Float(0x3fd7b13d),
        SkBits2Float(0x3f9ad36a)); // 1.66569f, 1.22091f, 1.67863f, 1.21767f, 1.6851f, 1.20958f
    path.cubicTo(
        SkBits2Float(0x3fda623e),
        SkBits2Float(0x3f96ae3a),
        SkBits2Float(0x3fdca93f),
        SkBits2Float(0x3f921eeb),
        SkBits2Float(0x3fdf253f),
        SkBits2Float(0x3f8dc4ab)); // 1.70612f, 1.17719f, 1.72391f, 1.14157f, 1.74332f, 1.10756f
    path.cubicTo(
        SkBits2Float(0x3fe0983f),
        SkBits2Float(0x3f8b12e5),
        SkBits2Float(0x3fe1d640),
        SkBits2Float(0x3f87f700),
        SkBits2Float(0x3fe3b340),
        SkBits2Float(0x3f857a4a)); // 1.75465f, 1.08651f, 1.76435f, 1.06223f, 1.77891f, 1.04279f
    path.cubicTo(
        SkBits2Float(0x3fe48740),
        SkBits2Float(0x3f8470fe),
        SkBits2Float(0x3fe62f40),
        SkBits2Float(0x3f8470fe),
        SkBits2Float(0x3fe7d741),
        SkBits2Float(0x3f843bef)); // 1.78538f, 1.0347f, 1.79832f, 1.0347f, 1.81126f, 1.03308f
    path.cubicTo(
        SkBits2Float(0x3fe2aa40),
        SkBits2Float(0x3f943182),
        SkBits2Float(0x3fda623d),
        SkBits2Float(0x3fa2498e),
        SkBits2Float(0x3fceff3a),
        SkBits2Float(0x3fae4f01)); // 1.77082f, 1.15776f, 1.70612f, 1.26787f, 1.61716f, 1.36179f
    path.cubicTo(
        SkBits2Float(0x3fce6039),
        SkBits2Float(0x3faf233e),
        SkBits2Float(0x3fcd2239),
        SkBits2Float(0x3faf584d),
        SkBits2Float(0x3fcc1939),
        SkBits2Float(0x3fafc26b)); // 1.61231f, 1.36826f, 1.60261f, 1.36988f, 1.59452f, 1.37312f
    path.cubicTo(
        SkBits2Float(0x3fcc1939),
        SkBits2Float(0x3faff77a),
        SkBits2Float(0x3fcc1939),
        SkBits2Float(0x3faff77a),
        SkBits2Float(0x3fcc4e39),
        SkBits2Float(0x3fb02c89)); // 1.59452f, 1.37474f, 1.59452f, 1.37474f, 1.59614f, 1.37636f
    path.cubicTo(
        SkBits2Float(0x3fcc1939),
        SkBits2Float(0x3fb02c89),
        SkBits2Float(0x3fcc1939),
        SkBits2Float(0x3fb02c89),
        SkBits2Float(0x3fcbe439),
        SkBits2Float(0x3fb02c89)); // 1.59452f, 1.37636f, 1.59452f, 1.37636f, 1.5929f, 1.37636f
    path.cubicTo(
        SkBits2Float(0x3fcbe439),
        SkBits2Float(0x3fb20a12),
        SkBits2Float(0x3fcb4539),
        SkBits2Float(0x3fb37d7d),
        SkBits2Float(0x3fc99d39),
        SkBits2Float(0x3fb3b28c)); // 1.5929f, 1.39093f, 1.58805f, 1.40227f, 1.57511f, 1.40389f
    path.cubicTo(
        SkBits2Float(0x3fc93339),
        SkBits2Float(0x3fb3e79b),
        SkBits2Float(0x3fc8c938),
        SkBits2Float(0x3fb41caa),
        SkBits2Float(0x3fc7f538),
        SkBits2Float(0x3fb41caa)); // 1.57188f, 1.40551f, 1.56864f, 1.40712f, 1.56217f, 1.40712f
    path.cubicTo(
        SkBits2Float(0x3fc7f538),
        SkBits2Float(0x3fb3e79b),
        SkBits2Float(0x3fc7f538),
        SkBits2Float(0x3fb3e79b),
        SkBits2Float(0x3fc7f538),
        SkBits2Float(0x3fb3b28c)); // 1.56217f, 1.40551f, 1.56217f, 1.40551f, 1.56217f, 1.40389f
    path.lineTo(SkBits2Float(0x3fc7c038), SkBits2Float(0x3fb3b28c)); // 1.56055f, 1.40389f
    path.cubicTo(
        SkBits2Float(0x3fc7c038),
        SkBits2Float(0x3fb4f0e7),
        SkBits2Float(0x3fc7f538),
        SkBits2Float(0x3fb66452),
        SkBits2Float(0x3fc78b38),
        SkBits2Float(0x3fb76d9e)); // 1.56055f, 1.4136f, 1.56217f, 1.42494f, 1.55894f, 1.43303f
    path.cubicTo(
        SkBits2Float(0x3fc3d137),
        SkBits2Float(0x3fbe4495),
        SkBits2Float(0x3fbf4336),
        SkBits2Float(0x3fc4123e),
        SkBits2Float(0x3fb80434),
        SkBits2Float(0x3fc76331)); // 1.52982f, 1.48647f, 1.49424f, 1.53181f, 1.43763f, 1.55771f
    path.cubicTo(
        SkBits2Float(0x3fb47f33),
        SkBits2Float(0x3fc90bac),
        SkBits2Float(0x3fb19932),
        SkBits2Float(0x3fcb5353),
        SkBits2Float(0x3faf1d31),
        SkBits2Float(0x3fce6f37)); // 1.41013f, 1.57067f, 1.38749f, 1.58848f, 1.36808f, 1.61277f
    path.cubicTo(
        SkBits2Float(0x3fa4592e),
        SkBits2Float(0x3fdb13d7),
        SkBits2Float(0x3f974e2a),
        SkBits2Float(0x3fe53bc1),
        SkBits2Float(0x3f896f25),
        SkBits2Float(0x3fee5a5f)); // 1.28397f, 1.71154f, 1.18207f, 1.79089f, 1.0737f, 1.86213f
    path.cubicTo(
        SkBits2Float(0x3f6b883f),
        SkBits2Float(0x3ffb691f),
        SkBits2Float(0x3f42f434),
        SkBits2Float(0x400367b2),
        SkBits2Float(0x3f184e28),
        SkBits2Float(0x4008611f)); // 0.920048f, 1.96415f, 0.761539f, 2.0532f, 0.594943f, 2.13093f
    path.cubicTo(
        SkBits2Float(0x3f184e28),
        SkBits2Float(0x4008611f),
        SkBits2Float(0x3f17e428),
        SkBits2Float(0x4008611f),
        SkBits2Float(0x3f17e428),
        SkBits2Float(0x40087ba7)); // 0.594943f, 2.13093f, 0.593325f, 2.13093f, 0.593325f, 2.13255f
    path.cubicTo(
        SkBits2Float(0x3effc044),
        SkBits2Float(0x400b47f5),
        SkBits2Float(0x3ed08c36),
        SkBits2Float(0x400e2eca),
        SkBits2Float(0x3e9edc28),
        SkBits2Float(0x401090f9)); // 0.499514f, 2.17627f, 0.40732f, 2.22161f, 0.310273f, 2.25885f
    path.cubicTo(
        SkBits2Float(0x3e5a5832),
        SkBits2Float(0x4012f328),
        SkBits2Float(0x3de40030),
        SkBits2Float(0x4014811a),
        SkBits2Float(0x3c1a7f9e),
        SkBits2Float(
            0x40158a66)); // 0.213227f, 2.29609f, 0.111328f, 2.32038f, 0.00942984f, 2.33657f
    path.lineTo(SkBits2Float(0x3c1a7f9e), SkBits2Float(0x401bf73d)); // 0.00942984f, 2.43697f
    path.cubicTo(
        SkBits2Float(0x3dc98028),
        SkBits2Float(0x401b580f),
        SkBits2Float(0x3e3fd82e),
        SkBits2Float(0x401a694b),
        SkBits2Float(0x3e8ca424),
        SkBits2Float(0x40191068)); // 0.098389f, 2.42725f, 0.187348f, 2.41268f, 0.27469f, 2.39163f
    path.cubicTo(
        SkBits2Float(0x3e94ec27),
        SkBits2Float(0x4018db59),
        SkBits2Float(0x3e9d3429),
        SkBits2Float(0x40188bc2),
        SkBits2Float(0x3ea4a82b),
        SkBits2Float(0x401856b3)); // 0.290864f, 2.38839f, 0.307039f, 2.38353f, 0.321596f, 2.38029f
    path.cubicTo(
        SkBits2Float(0x3eae982e),
        SkBits2Float(0x4018071c),
        SkBits2Float(0x3eb95c31),
        SkBits2Float(0x40179cfe),
        SkBits2Float(0x3ec34c34),
        SkBits2Float(0x40174d67)); // 0.341005f, 2.37543f, 0.362031f, 2.36896f, 0.381441f, 2.3641f
    path.cubicTo(
        SkBits2Float(0x3ec9ec36),
        SkBits2Float(0x40171858),
        SkBits2Float(0x3ed08c38),
        SkBits2Float(0x4016c8c1),
        SkBits2Float(0x3ed8003a),
        SkBits2Float(0x401693b2)); // 0.39438f, 2.36086f, 0.40732f, 2.356f, 0.421877f, 2.35276f
    path.cubicTo(
        SkBits2Float(0x3eda7c3a),
        SkBits2Float(0x4016792a),
        SkBits2Float(0x3eddcc3c),
        SkBits2Float(0x40165ea3),
        SkBits2Float(0x3ee0483c),
        SkBits2Float(0x4016441b)); // 0.426729f, 2.35115f, 0.433199f, 2.34953f, 0.438051f, 2.34791f
    path.cubicTo(
        SkBits2Float(0x3ee2c43d),
        SkBits2Float(0x40162993),
        SkBits2Float(0x3ee5403e),
        SkBits2Float(0x40160f0c),
        SkBits2Float(0x3ee8903f),
        SkBits2Float(0x4015f484)); // 0.442903f, 2.34629f, 0.447756f, 2.34467f, 0.454226f, 2.34305f
    path.cubicTo(
        SkBits2Float(0x3f1c082a),
        SkBits2Float(0x4012be17),
        SkBits2Float(0x3f422036),
        SkBits2Float(0x400e63d8),
        SkBits2Float(0x3f66fa40),
        SkBits2Float(0x40096a6a)); // 0.6095f, 2.29285f, 0.758304f, 2.22484f, 0.902256f, 2.14712f
    path.cubicTo(
        SkBits2Float(0x3f6a4a41),
        SkBits2Float(0x4009004c),
        SkBits2Float(0x3f6d3042),
        SkBits2Float(0x4008962d),
        SkBits2Float(0x3f708043),
        SkBits2Float(0x40081187)); // 0.915196f, 2.14064f, 0.926518f, 2.13417f, 0.939457f, 2.12607f
    path.cubicTo(
        SkBits2Float(0x3f7efe47),
        SkBits2Float(0x4005feef),
        SkBits2Float(0x3f868925),
        SkBits2Float(0x4003b748),
        SkBits2Float(0x3f8d5e28),
        SkBits2Float(0x40015519)); // 0.996067f, 2.09368f, 1.05106f, 2.05806f, 1.10444f, 2.02082f
    path.cubicTo(
        SkBits2Float(0x3f97b82b),
        SkBits2Float(0x3ffb691d),
        SkBits2Float(0x3fa1a82e),
        SkBits2Float(0x3ff388da),
        SkBits2Float(0x3fab9830),
        SkBits2Float(0x3feb7389)); // 1.18531f, 1.96415f, 1.26294f, 1.90261f, 1.34058f, 1.83946f
    path.cubicTo(
        SkBits2Float(0x3fb20332),
        SkBits2Float(0x3fe6450c),
        SkBits2Float(0x3fb80434),
        SkBits2Float(0x3fe0e181),
        SkBits2Float(0x3fbd6635),
        SkBits2Float(0x3fda3f99)); // 1.39072f, 1.79898f, 1.43763f, 1.75688f, 1.47968f, 1.70507f
    path.cubicTo(
        SkBits2Float(0x3fbf4336),
        SkBits2Float(0x3fd7f7f2),
        SkBits2Float(0x3fc12037),
        SkBits2Float(0x3fd5b04b),
        SkBits2Float(0x3fc2fd36),
        SkBits2Float(0x3fd33394)); // 1.49424f, 1.68725f, 1.5088f, 1.66944f, 1.52335f, 1.65001f
    path.cubicTo(
        SkBits2Float(0x3fc5e337),
        SkBits2Float(0x3fcf7881),
        SkBits2Float(0x3fc8c938),
        SkBits2Float(0x3fcbbd70),
        SkBits2Float(0x3fcbaf38),
        SkBits2Float(0x3fc8025d)); // 1.546f, 1.62086f, 1.56864f, 1.59172f, 1.59128f, 1.56257f
    path.cubicTo(
        SkBits2Float(0x3fceff39),
        SkBits2Float(0x3fc3a81e),
        SkBits2Float(0x3fd2843b),
        SkBits2Float(0x3fbf18cf),
        SkBits2Float(0x3fd5d43b),
        SkBits2Float(0x3fbabe8f)); // 1.61716f, 1.52857f, 1.64466f, 1.49294f, 1.67054f, 1.45894f
    path.cubicTo(
        SkBits2Float(0x3fd8503c),
        SkBits2Float(0x3fb7a2ab),
        SkBits2Float(0x3fda973d),
        SkBits2Float(0x3fb486c7),
        SkBits2Float(0x3fdca93e),
        SkBits2Float(0x3fb135d3)); // 1.68995f, 1.43465f, 1.70774f, 1.41036f, 1.72391f, 1.38446f
    path.cubicTo(
        SkBits2Float(0x3fe5c541),
        SkBits2Float(0x3fa2b3aa),
        SkBits2Float(0x3feb5c42),
        SkBits2Float(0x3f92be16),
        SkBits2Float(0x3ff15d44),
        SkBits2Float(0x3f82c882)); // 1.79508f, 1.27111f, 1.83875f, 1.14643f, 1.88566f, 1.02174f
    path.cubicTo(
        SkBits2Float(0x3ff1fc44),
        SkBits2Float(0x3f812008),
        SkBits2Float(0x3ff23144),
        SkBits2Float(0x3f7e1adf),
        SkBits2Float(0x3ff29b44),
        SkBits2Float(0x3f7a5fcc)); // 1.89051f, 1.00879f, 1.89213f, 0.992598f, 1.89536f, 0.978024f
    path.cubicTo(
        SkBits2Float(0x3ff47845),
        SkBits2Float(0x3f5fd830),
        SkBits2Float(0x3ff65545),
        SkBits2Float(0x3f455094),
        SkBits2Float(0x3ff6bf45),
        SkBits2Float(0x3f2a5ed9)); // 1.90992f, 0.874393f, 1.92448f, 0.770761f, 1.92771f, 0.66551f
    path.cubicTo(
        SkBits2Float(0x3ff33a44),
        SkBits2Float(0x3f0d5a87),
        SkBits2Float(0x3ff08943),
        SkBits2Float(0x3edf03ee),
        SkBits2Float(0x3fee7743),
        SkBits2Float(0x3ea352cf)); // 1.90022f, 0.552163f, 1.87919f, 0.435577f, 1.86301f, 0.318991f
    path.cubicTo(
        SkBits2Float(0x3feccf42),
        SkBits2Float(0x3e5c872d),
        SkBits2Float(0x3feb9142),
        SkBits2Float(0x3de4d179),
        SkBits2Float(0x3feaf242),
        SkBits2Float(0x3c04a4ae)); // 1.85008f, 0.215359f, 1.84037f, 0.111728f, 1.83552f, 0.0080959f
    path.lineTo(SkBits2Float(0x3fe02e3f), SkBits2Float(0x3c04a4ae)); // 1.75141f, 0.0080959f
    path.cubicTo(
        SkBits2Float(0x3fdff93f),
        SkBits2Float(0x3c6ec47e),
        SkBits2Float(0x3fe02e3f),
        SkBits2Float(0x3cb9b545),
        SkBits2Float(0x3fe0633f),
        SkBits2Float(
            0x3d04a60d)); // 1.74979f, 0.0145732f, 1.75141f, 0.0226694f, 1.75303f, 0.0323849f
    path.close();
    path.moveTo(SkBits2Float(0x3fe97f42), SkBits2Float(0x3f7b9e2e)); // 1.8242f, 0.982882f
    path.cubicTo(
        SkBits2Float(0x3fe91542),
        SkBits2Float(0x3f7eef21),
        SkBits2Float(0x3fe87642),
        SkBits2Float(0x3f81551a),
        SkBits2Float(0x3fe7d741),
        SkBits2Float(0x3f82fd94)); // 1.82096f, 0.995836f, 1.81611f, 1.01041f, 1.81126f, 1.02336f
    path.cubicTo(
        SkBits2Float(0x3fe6ce41),
        SkBits2Float(0x3f81bf39),
        SkBits2Float(0x3fe66441),
        SkBits2Float(0x3f8080dd),
        SkBits2Float(0x3fe66441),
        SkBits2Float(0x3f7e1ae4)); // 1.80317f, 1.01365f, 1.79993f, 1.00393f, 1.79993f, 0.992598f
    path.cubicTo(
        SkBits2Float(0x3fe66441),
        SkBits2Float(0x3f7c726a),
        SkBits2Float(0x3fe69941),
        SkBits2Float(0x3f7b340e),
        SkBits2Float(0x3fe6ce41),
        SkBits2Float(0x3f798b95)); // 1.79993f, 0.986121f, 1.80155f, 0.981263f, 1.80317f, 0.974786f
    path.cubicTo(
        SkBits2Float(0x3fe70341),
        SkBits2Float(0x3f78b758),
        SkBits2Float(0x3fe76d41),
        SkBits2Float(0x3f770edf),
        SkBits2Float(0x3fe7d741),
        SkBits2Float(0x3f770edf)); // 1.80479f, 0.971548f, 1.80802f, 0.965071f, 1.81126f, 0.965071f
    path.cubicTo(
        SkBits2Float(0x3fe84141),
        SkBits2Float(0x3f770edf),
        SkBits2Float(0x3fe8ab42),
        SkBits2Float(0x3f770edf),
        SkBits2Float(0x3fe8e041),
        SkBits2Float(0x3f7778fd)); // 1.81449f, 0.965071f, 1.81773f, 0.965071f, 1.81934f, 0.96669f
    path.cubicTo(
        SkBits2Float(0x3fe97f42),
        SkBits2Float(0x3f77e31b),
        SkBits2Float(0x3fe9e942),
        SkBits2Float(0x3f798b95),
        SkBits2Float(0x3fe97f42),
        SkBits2Float(0x3f7b9e2e)); // 1.8242f, 0.968309f, 1.82743f, 0.974786f, 1.8242f, 0.982882f
    path.close();

    float kTol = 0.25f;
    SkRect clipBounds = SkRect::MakeLTRB(0, 0, 14, 14);
    SimplerVertexAllocator alloc;

    int vertexCount = GrAATriangulator::PathToAATriangles(path, kTol, clipBounds, &alloc);
    CHECK(vertexCount == 0);
}

DEF_TEST(TriangulatorBugs, r) { test_crbug_1262444(r); }
#endif

#endif // SK_ENABLE_OPTIMIZE_SIZE
